Persistent Acoustic Sensing For Monitoring A Reactor Facility

Year
2021
Author(s)
Edna Cardenas - Idaho National Laboratory
Milton A. Garces - University of Hawai'i
Scott M. Watson - Idaho National Laboratory
James T. Johnson - Idaho National Laboratory
Jay D. Hix - Idaho National Laboratory
David L. Chichester - Idaho National Laboratory
File Attachment
a296.pdf595.48 KB
Abstract
Measurements over the past few years, taking place within the Multi-Informatics for Nuclear Operations Scenarios (MINOS) project, show that infrasound and low-frequency acoustic monitoring can detect, and often quantify, activities that occur on-site at a large research reactor. Observable activities include: crane translation, lifting, and lowering; differentiation between loaded and unloaded crane operations; access door opening and closing; vehicle operations; and cooling tower fan operation. Advanced data analytic and spectral feature extraction methods can be used to interpret selected signatures to reach a deeper understanding of different reactor activities. These measurements are being conducted using a network of smartphones that continuously operate in conjunction with cloud-based architectures. A recent addition to the system is the development and deployment of a real-time, cloud-based analytic framework that supports near-real-time alarming which can facilitate tip-and-cue protocols. This paper will present recent research advances in this area including studies to explore the transferability of learned parameters from one smartphone to another, the detectability of events from multiple sensors at different locations simultaneously, and the feasibility of porting analytical tools directly to the smartphones to allow edge computing with optimized configurations.